Osmoelectric siphon models for signal and water dispersal in wounded plants

Abstract When attacked by herbivores, plants produce electrical signals which can activate the synthesis of the defense mediator jasmonate. These wound-induced membrane potential changes can occur in response to elicitors that are released from damaged plant cells. We list plant-derived elicitors of membrane depolarization. These compounds include the amino acid l-glutamate (Glu), a potential ligand for GLUTAMATE RECEPTOR-LIKE (GLR) proteins that play roles in herbivore-activated electrical signaling. How are membrane depolarization elicitors dispersed in wounded plants? In analogy with widespread turgor-driven cell and organ movements, we propose osmoelectric siphon mechanisms for elicitor transport. These mechanisms are based on membrane depolarization leading to cell water shedding into the apoplast followed by membrane repolarization and water uptake. We discuss two related mechanisms likely to occur in response to small wounds and large wounds that trigger leaf-to-leaf electrical signal propagation. To reduce jasmonate pathway activation, a feeding insect must cut through tissues cleanly. If their mandibles become worn, the herbivore is converted into a robust plant defense activator. Our models may therefore help to explain why numerous plants produce abrasives which can blunt herbivore mouthparts. Finally, if verified, the models we propose may be generalizable for cell to cell transport of water and pathogen-derived regulators.


Introduction
The vast majority of invertebrate folivores get their food from the largest compartment in the leaf, the symplast. In order to do so, these organisms must first penetrate the leaf 's second largest compartment, the apoplast. Like breaking a window to enter a house, damage to the plasma membrane interface between the apoplast and the symplast can activate alarms. The danger for chewing herbivores is that broken cells release their contents into the apoplast. Some of these molecules act as damage-associated molecular patterns (DAMPs) that elicit immune responses in the host plant (Tanaka and Heil, 2021).
Since the perception of these compounds causes defense activation, it is in the interest of the herbivore to minimize their release, propagation, and action. This is especially important for a subset of DAMPs which can elicit the synthesis of the plant defense modulator jasmonoyl-isoleucine (JA-Ile; Howe et al., 2018;J. Wang et al., 2019) and its immediate precursor jasmonic acid (JA). Importantly, in the case of wounding, current evidence suggests that these elicitors act on jasmonate synthesis indirectly by first triggering membrane depolarization. Indeed, a genetic link between wound response membrane potential This paper is available online free of all access charges (see https://academic.oup.com/jxb/pages/openaccess for further details) changes and the activation of JA-Ile synthesis has been established (Mousavi et al., 2013). Here we focus principally on events that take place upstream of wound-induced membrane depolarization.
It is hard to imagine a plant in nature that completes its life cycle without being wounded at least once. Chewing herbivores damage plants in different ways. For example, leaf miners typically tunnel through the mesophyll then emerge as adults by breaking through the epidermis. Lepidopteran caterpillars typically feed from the surfaces of plants. Depending on their developmental stage, they may remove one or a few layers of cells or they may sever large veins. In all cases, chewing herbivores cause mixing of fluids from the symplast and apoplast. The leaf apoplast, comprised of cell walls, extracellular spaces, and xylem vessels, is characterized by a relatively low water potential and, in most cell walls, a surface tension component (McClendon, 1981). Here we suggest that these properties, coupled to the ability of cell membranes to depolarize and repolarize, are likely to be key to plant defense induction by feeding insects.
The majority of this review concentrates on apoplastic dispersal of membrane-depolarizing elicitors derived from the damaged symplasm. In this context, we summarize what is known about the nature of elicitors of membrane depolarization and JA/JA-Ile synthesis. We distinguish shortrange events caused by the wounding of one or several cells and long-range (organ to organ) signaling events caused by extensive damage to plant tissues and in particular to veins. The relationship between elicitor dispersion and apoplastic water potential is discussed. We do not cover herbivoreor pathogen-associated molecular patterns (HAMPs and PAMPs) and effectors derived from the herbivores themselves (reviewed in Snoeck et al., 2022). Throughout the review we use the general term 'elicitor': the mechanisms we propose could, in theory, transport diverse pathogenand herbivore-derived molecules. Additionally, we do not discuss cell wall integrity and its connection to jasmonate pathway induction (reviewed in Vaahtera et al., 2019;Wolf, 2022) or touch response electrical signaling; the text is restricted to invasive stimuli.

Small and large wounds and their relationship to electrical signals
Large and small wounds to aerial tissues can lead to jasmonate pathway activation. For example, small puncture wounds are sufficient to activate jasmonate-dependent defense gene expression in Arabidopsis cotyledons (Acosta et al., 2013). Single cell wounding in Arabidopsis roots causes membrane depolarization which then activates ethylene signaling (Marhavý et al., 2019). In the same study, and although single cell damageassociated electrical signaling in aerial organs was not studied, ablation of single cotyledon cells activated jasmonate signaling.
However, membrane depolarization is linked strongly to the activation of jasmonate synthesis (Farmer et al., 2020). Evidence suggests that membrane depolarizations can spread symplastically via plasmodesmata or along the plasma membranes of sieve elements (Fromm and Lautner, 2007;Hedrich et al., 2016). This might occur without the need for chemical modulators of membrane potential. However, other mechanisms to spread changes in membrane potential clearly exist. These involve the chemical elicitation of membrane depolarization by plant-derived elicitors generated or released upon wounding. These compounds can, in theory, be released even from wounds to single cells. Since small wounds trigger localized jasmonate signaling (Acosta et al., 2013;Marhavý et al., 2019), we assume that electrical signals originating from these wounds can travel short distances to nearby undamaged cells. We propose a mechanism that might determine the distance these elicitors travel.
Large wounds inflicted by herbivores inevitably damage veins. Herbivore damage to the primary leaf vasculature triggers leaf-to-leaf electrical signaling. These events are detectable with non-invasive surface electrodes as high-amplitude, long-duration slow-wave potentials (SWPs; Stahlberg et al., 2006). An SWP is characterized by a rapid membrane depolarization phase followed by a slow repolarization phase. Prescient work by Houwink (1935) on the sensitive plant Mimosa pudica defined 'two distinct ways of conduction'; that is, the work hinted at electrical signaling in both the phloem and xylem regions. Indeed, Fromm et al. (2013) presented evidence consistent with xylem to phloem electrical signaling in maize. Current research is consistent with this. In Arabidopsis, successful SWP propagation leading to the activation of jasmonate (JA-Ile) synthesis depends on several clade 3 GLUTAMATE RECEPTOR-LIKE (GLR) ion channels that act directly or indirectly as regulators of membrane depolarization. Among these genes are GLR3.3 and GLR3.6 (Mousavi et al., 2013). The main cellular localizations of GLR3.3 and GLR3.6 in expanded Arabidopsis leaves support roles for both the phloem and xylem in leaf-to-leaf wound signalling (Nguyen et al., 2018;Toyota et al., 2018). The principal vascular pools of GLR3.3 and GLR3.6 were found in the phloem and xylem, respectively. GLR3.3 protein was also detected in the epidermis (Nguyen et al., 2018). Our knowledge of the subcellular distributions of the GLRs in these cells is, however, still incomplete. At the subcellular level, the major GLR3.3 pools localized to the endoplasmic reticulum in phloem sieve elements. The major GLR3.6 pools were found in the tonoplasts of xylem contact cells. Additional, as yet undiscovered, localizations of these proteins in other vascular and extravascular cells and in other membranes (e.g. the plasma membrane) are likely to exist (Nguyen et al., 2018). Nevertheless, the cellular localizations of the main GLR3.3 and GLR3.6 pools indicate that xylem-phloem interactions must take place during SWP propagation (Nguyen et al., 2018).

Elicitors of membrane depolarization and jasmonate synthesis
What are the plant-derived elicitors of membrane depolarization that might activate jasmonate production? Table 1 gives a list of membrane-depolarizing elicitors from plants and from a Charophyte alga. The simplest of all these agents is the K + ion. The list includes the reactive oxygen species (ROS), hydrogen peroxide, polycations such as spermine and spermidine, polyanions such as the cell wall component oligogalacturonic acid, as well as DNA and a variety of nucleotides. From the list, it is seen that various sugars and amino acids can trigger membrane potential changes. There are also reports that the hormone indole acetic acid (IAA) can cause membrane depolarization. Table 1 also includes a number of specialized plant metabolites such as phenolic acids and terpenes, as well as several green leaf volatiles. Finally, among the peptides which can trigger membrane depolarization are reduced and oxidized glutathione and also systemin. There are likely to be other peptides that can affect membrane potential leading to jasmonate synthesis. For example, Vega-Muñoz et al. (2020) produced a valuable list of molecules including peptides that can induce jasmonate synthesis or signaling. We note that some of these molecules have yet to be tested for their ability to trigger membrane potential changes.
For the vast majority of the elicitors listed in Table 1, potential links to the activation of jasmonate synthesis or signaling have not been reported. However, several DAMPs that can trigger jasmonate pathway activation are known. These include pectate/pectin-derived cell wall fragments (in particular oligogalacturonides; Doares et al., 1995), the peptide systemin (Moyen and Johannes, 1996), and more recently l-glutamic acid (Glu) which stimulates the expression of jasmonateresponse genes (Toyota et al., 2018). A common feature of these diverse compounds is that they all trigger membrane depolarization (Thain et al., 1990;Moyen and Johannes, 1996;Dennison and Spalding, 2000;Shao et al., 2020). We are unaware of reports of the long-distance transport of oligogalacturonides in wounded plants. Concerning systemin, current evidence suggests that this peptide is not necessary for damage-response jasmonate pathway activation in leaves distal to wounds (Wang et al., 2018). However, the amino acid Glu is of special interest since it is a potential ligand for the clade 3 GLR proteins that control membrane depolarization in tissues distal to wounds.
Glu is implicated in diverse signaling processes in plants and has been studied as a potential signal molecule for decades (Forde and Lea, 2007;Qiu et al., 2020;Liao et al., 2022). Interest in the effects of Glu on ion fluxes was prompted by the discovery of GLR genes in the Arabidopsis genome (Lam et al., 1998). This helped to stimulate research on the effects of exogenous Glu on membrane potentials in plants. For example, Dennison and Spalding (2000) showed that Glu triggered membrane depolarization in Arabidopsis root tip cells and that this was preceded by a spike-like increase in cytosolic Ca 2+ levels. Glu was also shown to trigger membrane depolarization in Arabidopsis mesophyll cells (Meyerhoff et al., 2005). Further work showed that like Glu, the amino acids glycine, alanine, asparagine, cysteine, and serine all triggered membrane depolarization in Arabidopsis hypocotyl cells (Stephens et al., 2008). In each case, these amino acids elicited membrane depolarizations which were GLR3.3 dependent. Consistent with this, Glu can bind directly to several clade 3 GLRs. In GLR3.3, Glu is bound in the absence of water, whereas the smaller glycine is bound in the presence of two water molecules (Alfieri et al., 2020). A similar situation pertains for glycine binding to GLR3.2  and for serine binding to GLR3.4 . Therefore, amino acid binding to clade 3 GLRs might depend to some extent on water potential.
Further interest in Glu as a signaling mediator came from the finding that several clade 3 GLR genes underlie electrical signaling in the aerial tissues of wounded Arabidopsis (Mousavi et al., 2013). Toyota et al. (2018) revealed that Glu could trigger jasmonate-response gene expression in Arabidopsis leaves. Importantly, the same study provided strong genetic evidence that extracellular Glu levels increase after wounding. Interestingly, the effect of exogenous Glu on membrane depolarization appears to be both concentration and plant specific; that is, one compound, Glu, can elicit at least three types of electrical signals in plants. For example, 1 mM Glu triggered action potentials in barley leaves (Felle and Zimmermann, 2007). However, Zimmermann et al. (2009) found that an initial treatment of a barley leaf with 10 mM Glu triggered an action potential, but a second treatment of the leaf with 10 mM Glu triggered a hyperpolarization typical of a system potential. More recently, treatment of the cut ends of Arabidopsis roots or hypocotyls with 50-100 mM Glu was shown to trigger SWP-like membrane depolarizations in Arabidopsis leaves (Shao et al., 2020). How can one compound stimulate the production of electrical signals as diverse as action potentials and SWPs? We suggest that this is due to the fact that Glu may act as an excitotoxin in plants as is known for its effects on animal cells (Ankarcrona et al., 1995). It is possible that, in the constant presence of high Glu levels, cell membranes may remain depolarized for too long, blocking physiological functions. This raises the possibility that other endogenous SWP elicitors might be excitotoxins. Such molecules might act at the cell surface or, for full activity, might need to be imported into cells. If so, their action may lead to particularly efficient water shedding from the elicited cell into the apoplast.

Elicitor dispersal and the apoplast
The thin, shell-like cell walls of the leaf mesophyll have low water potentials in the range of -0.3 MPa (Meinzer and Moore, 1988;Wright and Beattie, 2004). Interestingly, pathogens manipulate the apoplast to increase water potential (Xin et al., 2016; Krol et al. (2010) GLVs, green leaf volatiles; esDNA, extracellular self-DNA; NA, not analysed. Only JA responses induced by exogenously applied elicitors were referred to here. Hernandez and Lindow, 2019). To what extent chewing insects do this is unclear. However, sudden water fluxes into the apoplast caused by herbivore feeding should spread quickly; that is, fluid released from the symplasm of herbivore-damaged cells is expected to 'wet' the apoplast and, in doing so, carry with it symplast-derived elicitors of membrane depolarization. This or a similar process is likely to occur when one or a few cells are wounded. Elicitor release from damaged cells would be of little use to plants if the elicitor could not be dispersed effectively. Part of the mechanism of elicitor dispersal will clearly depend on diffusion. For example, the diffusion-driven spread of elicitors such as amino acids through the apoplast is linked tightly to cytosolic Ca 2+ waves (Bellandi et al., 2022). Here, we propose additional mechanisms which may explain apoplastic elicitor dispersal in wounded plants. The models are based on mechanisms involving tightly associated changes in membrane potential, cell volume, and apoplastic water potential. Insights into the relationships of these processes came, for example, from early work on Chara corallina. Experiments with these giant algal cells revealed cell length shortening during membrane depolarization (Oda and Linstead, 1975). Osmoelectric motors involving transmembrane water fluxes underlie the opening and closing of stomata (e.g. Hill and Findlay, 1981;Roelfsema and Hedrich, 2005), a process which can be surprisingly rapid in some ferns (Cardoso et al., 2019). Closely related mechanisms can operate even more rapidly, controlling fast movements associated with prey capture by carnivorous plants (Hill and Findlay, 1981). Also, generally at slower scales, osmotic mechanisms can explain reversible turgor-driven diel movements of leaves and floral organs (Hill and Findlay, 1981) and the cell swelling that underlies plant growth (Forterre, 2013). Here, we add a new aspect; the involvement of elicitor compounds that may drive rapid osmoelectric processes by depolarizing membranes. We herein use the assumption that plant cells in general lose water when their membranes depolarize. Moreover, we predict that osmoelectric siphon mechanisms can help explain elicitor transport in wounded plants. In summary, we propose 'push-pull' mechanisms in which cells first shed water into the apoplast when their membranes depolarize upon contact with elicitors. Critically, the same cells can take up water again when their membranes repolarize (Fig. 1).
A cell-level osmoelectric siphon model for elicitor dispersal from small wounds A model for apoplastic elicitor dispersal from small wounds (e.g. to one or a few cells in the epidermis or mesophyll) is shown in Fig. 1. The model shows the release of membrane depolarization elicitors from single cell wounds. The essence of the model is that these compounds collapse membrane potentials in surrounding undamaged cells, and that those cells then release water into the apoplasm. The walls of neighboring cells will then attract this water and, in the process, this will carry elicitors further away from the wound. Added to this, and not shown in the model, diffusion will also disperse signal molecules until they are diluted out or they decay. In this way, elicitors from wounds will radiate away from damaged cells. This mechanism depends on low apoplastic water potentials in the undamaged plant. However, apoplastic water potentials are likely to vary depending on environmental conditions. A prediction based on this model is that the lower the apoplastic water potential, the better the spread of elicitors in the apoplast. This may also be the case for large wounds that rupture the vasculature. Such wounds, unlike wounds to the epidermis or mesophyll, cause direct damage to the phloem and xylem.
Elicitor transport in the xylem in relation to electrical signaling From the moment that a vein is severed by a feeding insect, and in the seconds that follow, the water potentials of the xylem , further promoting elicitor distribution in the apoplast. The membranes will then repolarize and their cells will take up water again. In this way, rings of 'wet' apoplasm will spread radially from small wounds. After dispersing, the process will terminate when the elicitor concentration falls below a critical level or when the elicitor decays. This process is linked to triggering jasmonate (JA) synthesis. Dep = membrane depolarization; Rep = membrane repolarization.
and phloem must change. Damage to the phloem must lead to some loss of pressure, no matter how fast phloem occlusion occurs. In parallel, fluid from damaged tissues is drawn from the wound site into vessels as their tension is released suddenly (Stahlberg and Cosgrove, 1992). This sap will essentially compete with air to be sucked into the xylem. Importantly, the sap carries with it membrane depolarization elicitors. The spread of the SWP is driven by these elicitors of membrane depolarization as they travel through the xylem of the wounded plant (e.g. Evans and Morris, 2017;Kurenda et al., 2019). This latter point links recent work on Arabidopsis with the historically important proposal for the existence of 'Ricca's factors'. These xylem-mobile factors were proposed to control distal wound-response leaf movements in the sensitive plants Mimosa spegazzinii and M. pudica (Ricca, 1916(Ricca, , 1926. A brief history of Ricca's factors is given in Box 1. In order to initiate SWPs that can travel from leaf to leaf, herbivores must damage the basipetal primary veins  in the region illustrated in red in Fig. 2A. Once initiated, SWPs travel to distal leaves that share vascular connections with the wounded leaf (Mousavi et al., 2013). SWPs travel through the primary veins of Arabidopsis at apparent velocities of 6-9 cm min -1 (Mousavi et al., 2013;Nguyen et al., 2018). The elicitors of membrane depolarization that are transported from leaf to leaf must travel at similar speeds to these electrical signals. Membrane depolarization in leaves distal to wounds takes place prior to peak cytosolic Ca 2+ transients (Nguyen et al., 2018). Similarly, peak increases in cytosolic Ca 2+ levels followed flagellin-induced membrane depolarization in Nicotiana benthamiana mesophyll cells (Li et al., 2021).
A likely driver of elicitor transport is transpiration, although other mechanisms such as turbulent diffusion in the xylem have been proposed (Vodeneev et al., 2012). In the case of Arabidopsis, and as illustrated in Fig. 2B, electrical signals travel basipetally from sites of damage to the primary vein and then disperse into leaves that share direct vascular connections with the damaged leaf. We note that, in the damaged leaf, electrical signals can travel towards the plant center. One explanation for this is that all leaves essentially compete for water supplied by the root. When the petiolar primary vein of one leaf is severed, leaves sharing vascular connections with this leaf outcompete its reduced transpiration, reversing xylem water flow in the severed petiole. This might help to explain the fact that the apparent velocity of the SWP in Arabidopsis is faster in the distal unwounded leaf than in the wounded leaf (Mousavi et al., 2013).
Here we consider transpiration as a primary driver of SWP elicitor transport. SWP generation is extremely robust in wildtype plants. When intact wild-type Arabidopsis plants were placed in the dark for 3 d and then transferred to the light, the plants displayed typical SWPs (Fotouhi et al., 2022). In the same study, caterpillar-damaged wild-type plants that lacked much if not most of their laminar tissues were still capable of propagating SWPs. In this case, the SWP propagation velocity was 2-fold slower in these damaged leaves relative to leaves with intact laminas. While transpiration appears to play an important role in xylem elicitor dispersion, careful studies of the link between transpiration and SWP propagation hint at additional mechanisms involved in elicitor transport. For example, Stahlberg et al. (2005) concluded that transpiration rate was unlikely to be the only determinant of SWP propagation in sunflower leaves. Furthermore, SWP signaling needs to function at different times of the day and under different soil water potentials. For this, a mechanism related to that proposed for short-distance signaling in Fig. 1 may act together with transpiration-driven elicitor transport.

An osmoelectric siphon model for elicitor dispersal in the vasculature
The relative positions of the xylem and phloem in an Arabidopsis primary vein are shown in Fig. 3A. In healthy plants including trees, the xylem and phloem operate together under diverse conditions (e.g. Spicer, 2014;Stroock et al., 2014;Van Bel, 1990;Zwieniecki et al., 2004;Konrad et al., 2019). We assume that this is also the case in the wounded plant and that there is a coordinated function of the phloem and xylem in leaf-to-leaf electrical signaling. Figure  3B illustrates the positions of fields of cells associated with the xylem and phloem. The phloem field includes sieve elements, companion cells, and the many associated cells which are usually referred to as phloem parenchyma. The phloem electrical field is embedded in a panvascular electrical field which includes that of xylem contact cells. From an electrophysiology perspective, we assume that cells in these two fields can be depolarized in a coordinated manner upon attack. Herein, we envisage that the vasculature, and in particular the phloem, acts as a kind of capacitor (Fotouhi et al., 2022). In this view, the ability of the phloem to discharge (depolarize) and repolarize rapidly and fully is vital for the electrical activities of other vascular cells.
Both cell rupture and simply compressing cells without breaking them may trigger electrical events. Regarding nondamaging pressure changes, previous work led to the hypothesis that compressive forces on xylem contact cells are associated with SWP signaling (Farmer et al., 2014). Here, based on recent experimental observations, we extend this 'squeeze cell' hypothesis to larger fields of vascular cells. Primary veins in Arabidopsis leaves swell as wound-response electrical signals travel from leaf to leaf . In parallel, deformations of the petiole surfaces were detected (Fig. 3C). Both of these observations are consistent with water fluxes in the tissues of wounded plants. We speculate that increased axial water fluxes through vessels in damaged plants may be coupled to radial water shedding from the xylem into nearby cell walls.
In Fig. 3D we envisage an electrical field associated with the phloem. Other vascular cells, including those in the xylem region, form a second theoretical field. We speculate that these fields interact and operate together in wound-response electrical signaling. How this occurs is unknown. However, certain features of the cell matrix that comprises the Arabidopsis vascula-ture may provide clues. The Arabidopsis primary vein (Fig. 3A), unlike the mesophyll, lacks intercellular air spaces. This may facilitate extensive radial interactions between vascular cells

Box 1. Ricca's factors in a nutshell
For decades, the touch-and wound-induced movements of Mimosa pudica have intrigued biologists. This plant (along with related species such as M. spegazzinii) became 'the' model for touch-response signaling and for leaf-to-leaf wound signaling. These plants attracted the attention of physiologists including Henri Dutrochet, Wilhelm Pfeffer, and Gottlieb Haberlandt. Each of these scientists and some of their forerunners pondered possible mechanisms of signal propagation within touch-stimulated or damaged Mimosa. Building on their work, Ricca (1916Ricca ( , 1926 showed that factors present in extracts from M. pudica leaves could travel through dead tissues or even through glass tubes to elicit distal leaf movements in this plant. This led to a sustained but ultimately unsuccessful effort to isolate these factors (e.g. Fitting, 1930Fitting, , 1936Van Sambeek et al., 1976). Meanwhile, Houwink (1935) made the connection between leaf movements in M. pudica and electrical signals in this plant. Houwink's work supported Ricca's proposal that what are now called Ricca's factors (RFs) travel from wounds through the xylem to distal leaves. Moreover, Houwink specifically associated RFs to damage-induced membrane depolarizations that he called 'variations' and that are now known as either 'variation potentials' or 'slow wave potentials' (SWPs; as used herein). It is noteworthy that RFs were proposed to elicit the longduration depolarization phase of the SWP (Houwink, 1935).
For years, the RF concept remained Mimosa specific. However, Barbara Pickard broadened the definition of RFs to xylem-mobile electrical signal-inducing substances from plants (Van Sambeek et al., 1976). At this point, the generality of the RF concept became increasingly clear-all plants should have RFs. However, the roles of these putative substances in plants other than M. pudica remained unclear. Pickard evoked a possible role for SWPs in plant defense (Van Sambeek et al., 1976). This later turned out to be the case when electrical signals produced in response to wounding were genetically linked to the activation of the synthesis of jasmonate in Arabidopsis (Mousavi et al., 2013). The current perspective is that xylem-mobile substances underlie wound-response leaf-to-leaf electrical signaling in Arabidopsis (Evans and Morris, 2017). Indeed, evidence supports a role for xylem-mobile RFs in electrical signaling leading to both minute leaf movements in wounded Arabidopsis and jasmonate signaling induction in this plant . GLR proteins appear to act downstream of RFs to control leaf movements and jasmonate pathway activation in Arabidopsis. What, then, is the via plasmodesmata; such interactions may be important for wound-response electrical signaling. To function effectively in defense as activators of jasmonate synthesis, electrical signals need to be propagated axially to distal leaves. This is facilitated by xylem-borne membrane depolarization elicitors ('Ricca's factors') that essentially 'bridge the gap' between leaves. Figure 2B illustrates that in order to elicit distal defense signaling, elicitors from damaged leaves must be transported basipetally from the damaged leaf before they can enter the transpiration stream of an undamaged leaf. Plants that have been badly damaged by herbivores may have a reduced capacity for transpiration. However, such plants still produce SWPs, albeit of slower velocities than those of intact plants (Fotouhi et al., 2022). In cases like these, we speculate that osmoelectric siphons may help to facilitate basipetal elicitor transport in damaged leaves so that elicitors can be channeled towards transpiration streams in leaves distal to wounds. Xylem contact cells are often found as stellate arrangements organized around vessels. Such a cluster from the mid-region of an Arabidopsis petiole is shown in Fig. 4A. However, depending on their position in the primary vein, these elongated cells can have variable diameters. At the base of the Arabidopsis petiole, some contact cells that are adaxially positioned relative to vessels can be greatly enlarged (Fig. 4B). These petiole-base contact cells should, in theory, have a large capacity to shed water. In the model, the membranes of vessel-associated cells in damaged leaves come into contact with plant-derived elicitors. These cells then depolarize and lose water which is drawn away into the apoplast (Fig.  4C). As the contact cells repolarize, they preferentially take up water from vessels, thereby pulling water and elicitors along the xylem (Fig. 4D).
The main assumption of the model is that xylem contact cells and other core vascular cells release water when their membranes depolarize. Much of this water may originate in vacuoles. Indeed, changes in vacuole sizes have already been linked strongly to electrical signaling. For example, electrical signals in M. pudica trigger rapid pulvinar turgor changes, water movements, and changes in vacuole size and shape (e.g. Sibaoka, 1991). Could similar but more cryptic events take place in Arabidopsis? Intriguingly, the vacuoles of Arabidopsis xylem contact cells show remarkably variable volumes depending on whether or not vein samples are prepared in the presence or absence of sorbitol (Nguyen et al., 2018). It will therefore be of interest to investigate contact cell vacuole dynamics upon wounding. A further aspect that needs testing is the possibility that the velocity and/or extent of leaf-to-leaf electrical signaling will depend in part on leaf water potentials.

Relationship of osmomelectric siphon models and mechanohydraulic models
Our osmoelectric models differ from current mechanohydraulic models used in studies of cell growth (e.g. Long et al., 2020). Mechanohydraulic models are generally used to explore irreversible cell growth trajectories. The osmoelectric models herein are based on reversible transmembrane charge redistribution and water fluxes leading to reversible (elastic) changes in cell volume. We note that cells adjacent to wounds divide in the hours that follow wounding (Hoermayer et al., 2020). The osmoelectric mechanisms proposed herein should work over shorter time frames (tens of seconds) and their relationship to cell division, if any, is yet to be explored. Although mechanohydraulic and osmoelectric models have different applications, they are united by hydraulics. Therefore, interactions between the two types of model are possible.

Testing osmolectric siphon models
Following genetic tests to ensure the biological relevance of a given elicitor, the spatial extent of elicitation output (e.g. jasmonate signaling and electrical signaling) could be established with reporter genes and, where possible, surface electrodes. Even more challenging tests will involve measuring the degree of water shedding from elicited cells. This may be problematic in part due to the fact that cell-specific apoplastic water potentials (matric potentials), apoplastic solute compositions, and conductivities and ionic strengths are not yet measurable using non-damaging methods in intact plants. Elicited cells should lose turgor and this could be measured, for example with atomic force microscopy. Force sensors such as those employed in Kurenda et al. (2019) may also be useful at the tissue level. A potential caveat is that water influx into the apoplast might, in addition to affecting turgor, alter cell wall properties, for example causing wall swelling similar to that observed in brown algae (M. . That possibility would need to be taken into account. Pico gauges (Knoblauch et al., 2014) could be used to probe intracellular pressures. However, the possibility that puncturing cells might itself trigger membrane depolarization will need consideration. Osmolyte treatments may be considered. For example, the above wild-type level of jasmonate signaling observed in Arabidopsis korrigan1 (kor1) cell wall mutants was suppressed by hyperosmotic treatments (Mielke et al., 2021). However, we note that in the absence of membrane depolarization elicitors, osmolytes alone may not be sufficient to strongly depolarize the cell membranes. Moreover, key to the models we present are apoplastic water fluxes, and these may be reduced or abolished if cells are partially dehydrated in hyperosmotic conditions.

The elicitation of jasmonate synthesis after wounding
Xylem contact cells are sites of wound-response jasmonate precursor synthesis in leaves distal to wounds Gasperini et al., 2015). Jasmonate precursor synthesis in these cells follows SWP signaling; however, the key regulatory steps that allow the initiation of jasmonate synthesis in these cells are unknown. More is known about the synthesis of jasmonates during reproductive development. Developmental jasmonate production in flowers requires lipases (Ishiguro et al., 2001), and these enzymes are also known to play roles in jasmonate synthesis initiation in wounded leaves (Ellinger et al., 2010). The activity of such lipases may depend on wound-response increases in cytosolic Ca 2+ which probably regulate postwounding jasmonate synthesis (X. . Three other factors might affect jasmonate synthesis in contact cells. Each of these is related to the SWP: membrane depolarization, changes in water potential, and changes in intra/intercellular pressures. Genetic approaches have shown that intracellular pressures can trigger jasmonate responses (Mielke et al., 2021). Also concerning pressure, we note that mechanosensitive ion channels are expressed in plastids which can deform in their absence (Haswell and Meyerowitz, 2006). Alternatively, it is possible that plasma membrane potential changes and/or changes in water potential might affect endomembranes including those of plastids. Such mechanisms could, in theory, trigger galactolipid phase changes which then allow lipases to generate jasmonate precursors. The potential contributions of membrane depolarization, rapid cell water potential changes, and tissue pressure changes to the wound-activated initiation of jasmonate synthesis need investigation. In any case, feeding herbivores need to minimize the activation of jasmonate synthesis.

Potential relevance in biotic and abiotic stress
The mandibles of herbivorous insects have forms that are adapted to their host plants (Bernays, 1991). Chewing insects generally cut plant tissues using sharp mandibles, avoiding crushing of cells surrounding the sites they feed on. There are exceptions to this. For example, some insect larvae tear leaf Brown dots are placed on several xylem vessels. Scale bar=10 μm. (C) Model for a mechanism to draw water and elicitors along xylem vessels and into the apoplasm in a wounded plant. Following damage to the vasculature, elicitors (red E) are released into xylem vessels and drawn along the transpiration stream. These elicitors depolarize contact cell membranes which then shed water. Cells with depolarized membranes are indicated in red. (D) Upon repolarization, water from vessels is preferentially reloaded from the xylem into contact cells. This mechanism is envisaged to operate in wounded leaves and to allow elicitor transport to undamaged leaves distal to wounds. Repolarizing cells are indicated in green. The model assumes that there is a largely one-way flow of water from vessels to contact cells. Jasmonate synthesis is not indicated. For (A) and (B) images were prepared using cryo-fracture electron microscopy of leaves and petioles from 4.5-week-old Arabidopsis plants. Dep = membrane depolarization; Rep = membrane repolarization.
tissues (Bernays and Janzen, 1988) and some lepidopterans use their mandibles to generate sounds (Brown et al., 2007). However, all these herbivores have developed feeding strategies that allow the rapid procurement and digestion of food, thereby ensuring their fast growth (Bernays and Janzen, 1988). This is facilitated by having sharp mandibles. Here, we propose another potential effect of mandible wear-this time on the plant itself.
If osmoelectric siphons function in plant defense, the degree to which a feeding insect activates the jasmonate pathway will depend in part on its mandibles. As a widespread antiherbivore defense mechanism, plants commonly deploy vitreous, silicon-based abrasives (Debona et al., 2017;Coskun et al., 2019;Johnson et al., 2021) or crystalline deposits such as calcium oxalate (Nakata, 2003) that can blunt insect mandibles (Korth et al., 2006;Massey and Hartley, 2009;Park et al., 2009). This is thought to reduce the ability of herbivores to digest plant tissues efficiently, therefore retarding herbivore development (Bernays, 1991). In some cases, defense chemicals generated upon wounding are thought to occlude the mouthparts of insects that feed by sucking rather than chewing (Bai et al., 2022). What are the consequences of insect mandible/mouthpart blunting for the plant? For example, is it the same to be clipped by razor-sharp mouthparts or by mandibles that have been blunted and worn? Based on our models for elicitor dispersal, we propose that mandible wear will affect plant defense response induction. With relevance to the feeding mode of the herbivore, it is likely that, when vascular tissues are crushed rather than severed cleanly, elicitor-rich fluids enter the xylem more efficiently than does air. Clearly, the herbivore must minimize the release of symplast-derived elicitors of membrane depolarization into the apoplast. Herbivores can do so by severing tissues with sharp mandibles. Finally, the models presented could be of interest in terms of drought stress. For example, the model in Fig. 1 emphasizes the fact that a dying cell sheds its water into the apoplast. Under severe drought stress, living cells will start to lose their membrane potentials and will shed water. Nearby cells will attract and gather this water from the dying cell, thereby minimizing rapid evaporative water loss from the tissue.

Conclusion
We present models for the transport of water, elicitors, and effectors in herbivore-(or pathogen) attacked plants. In the models we develop, chemical elicitors trigger membrane potential changes and water fluxes that are associated with the activation of the jasmonate pathway. These osmoelectric siphon models involve elicitor-induced exchange of water between the symplast and the apoplast correlated with changes in membrane potential. At more negative membrane potentials, cell turgor is maintained; however, turgor is lost when membrane potentials collapse. We speculate that electrical signaling in attacked plants may, in addition to other mechanisms, exploit the fluid continuum of the apoplast to actively disperse elicitors. This would allow plants to couple and coordinate membrane depolarizations within and between cell layers. A prediction is that the more turgid a cell is, the greater its response to elicitation. Throughout the text, we assume that the same elicitor triggers both membrane depolarization and subsequent water shedding. However, the possibility that multiple elicitors are involved in one of these two processes needs consideration.
For small (non-vascular) wounds, we propose a mechanism in which elicitors may be dispersed efficiently over short distances in the apoplasm so that even small quantities of these molecules are carried away from the wound site. We distinguish this first model from a second model for elicitor dispersion within the vasculature of severely wounded tissues. Leaf-to-leaf electrical signaling must be robust enough to function day and night and under constantly varying environmental conditions. To explain this robustness, mechanisms going beyond transpiration have been evoked herein. This second model involves the xylem and the phloem. Decades of research indicate that the phloem is of vital importance in axial electrical signaling through veins. Phloem electrical signals triggered by non-damaging stimuli are generally restricted to the stimulated organ and these signals can be relatively fast depending on the plant species (Fromm and Lautner, 2007). It is not yet known whether phloem electrical signaling in response to non-damaging stimuli requires phloem-borne chemical mediators of membrane potential change. However, severe wounding of aerial tissues triggers leaf-to-leaf electrical signaling in a process that clearly requires the long-distance transport of membrane depolarization elicitors through the xylem. Viewed simply, the phloem in the wounded plant offers a fast route for electrical signaling while the xylem offers a slower route. Elicitors which travel through the xylem are likely to stimulate electrical signaling in the phloem. That is, in the presence of plantderived xylem-borne elicitors, the phloem electrical signal which would otherwise be restricted to the damaged leaf can overcome an effective barrier to reach distal leaves. If verified, the models developed herein may also help to explain the movement of herbivore-and pathogen-derived effectors. In the future, it will be interesting to verify the relationships (if any) between osmoelectric siphon models and mechanohydraulic models. Lastly, some aspects of the models we present may be relevant to the study of cell-to-cell water transport in drought-stressed plants.